Automatic Mesh-Generation (FEM/SPH) for HVI-Simulations of Arbitrary Rotational Symmetric Impactors

2019 15th Hypervelocity Impact Symposium Pub Date : 2019-04-14 DOI:10.1115/hvis2019-080

Marvin Becker, M. Seidl, M. Mehl, M. Souli

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引用次数: 1

Abstract

For the numerical description of high velocity impact, Smooth-Particle-Hydrodynamics (SPH) has gained more and more interest. The standard Lagrangian Finite-Element (FE) approach has difficulties in describing large deformations and fracture. However, a simulation based on SPH only is very expensive due to the small size of the particles. A well adopted solution to this is to couple both methods, using SPH only where it is necessary, and capturing the outer boundary conditions with a bias FE-mesh correctly - without considerable extra computational cost. We apply such a hybrid approach in LS-DYNA® for the characterization of threats in terminal ballistics. Different meshing approaches for the projectile and target were implemented to guarantee an optimal initial condition. The particle size and the required size of the SPH-region were studied to exclude discretization effects. Exemplarily, a projectile surrogate with simplified geometry is investigated for a fixed impact velocity and two different angles of obliquity. A qualitative comparison between experiments, observed with X-ray cinematography, reveals a good potential of this approach towards predicting fracture and ricochet during high velocity impact events.

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任意旋转对称冲击器hvi仿真的自动网格生成(FEM/SPH)

对于高速碰撞的数值描述，光滑粒子流体力学(SPH)得到了越来越多的关注。标准拉格朗日有限元(FE)方法在描述大变形和断裂时存在困难。然而，由于粒子尺寸小，仅基于SPH的模拟是非常昂贵的。一个很好的解决方案是将这两种方法结合起来，只在必要的地方使用SPH，并正确地用偏置fe网格捕获外部边界条件-没有相当大的额外计算成本。我们在LS-DYNA®中应用这种混合方法来表征终端弹道中的威胁。为保证初始条件的最优，对弹丸和目标采用了不同的网格划分方法。为了排除离散化效应，研究了sph区的粒径和所需粒径。举例来说，研究了一种几何简化的弹丸替代物，该替代物具有固定的冲击速度和两种不同的倾斜角度。通过x射线摄影观察到的实验间的定性比较，揭示了该方法在预测高速撞击事件中的断裂和弹跳方面的良好潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2019 15th Hypervelocity Impact Symposium

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